Structure of driving unit in drum type washing machine

ABSTRACT

Structure of driving unit in a drum type washing machine including a tub mounted inside of a cabinet, a drum mounted inside of the tub, a shaft connected to the drum mounted inside of the tub for transmission of a driving force from a motor to the drum, a front bearing and a rear bearing mounted on an outer circumference of the shaft at opposite end portions thereof respectively, a bearing housing built in a central portion of a rear wall of the tub for supporting the front bearing, a rotor composing the motor together with the rotor, and coupled to the rear end portion of the shaft, a stator fixed to the tub rear wall inward of the rotor to compose the motor together with the rotor, a connector serration coupled to the outer circumference of the shaft in front of the rear bearing and fixed to the rotor, for transmission of a rotating power from the rotor to the shaft, and a bearing bracket fixed to the rear wall of the tub to cover an outside of the rotor and support the rear bearing, thereby reducing noise, repair and power loss, by improving a structure of a driving unit, improving a product reliability, by improving a washing capability, and improving a productivity by improving workability in fabrication of components of the driving unit.

This application is a continuation of U.S. application Ser. No. 10/942,795 filed Sep. 17, 2004 now U.S. Pat. No. 6,914,363, which is itself a continuation of U.S. application Ser. No. 10/231,314 which was filed Aug. 30, 2002, which is itself a continuation of U.S. application Ser. No. 09/624,144, which was filed Jul. 21, 2000, and which now has issued as U.S. Pat. No. 6,460,382 on Oct. 8, 2002. The disclosures of the previous applications are incorporated by reference herein.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a drum type washing machine, and more particularly, to a structure of a driving unit in a drum type washing machine.

2. Background of the Invention

In general, a drum type washing, making washing by using friction between a drum rotated by a motor and laundry in a state detergent, washing water, and the laundry are introduced into the drum, provides effects of beating and rubbing washing, but gives almost no damage to the laundry, and shows no entangling of the laundry. A structure of a related art drum washing machine will be explained with reference to FIG. 1. FIG. 1 illustrates a longitudinal section of a related art drum type washing machine, provided with a tub 2 mounted inside of a cabinet 1, a drum 3 rotatably mounted on a central portion of inside of the tub 2. There is a motor 5 a under the tub 2 connected with a pulley 18. There is a drum shaft connected to a rear of the drum 3, to which a drum pulley 19 is coupled. And, the drum pulley 19 on the drum shaft and the motor pulley 18 connected to the motor 5 a are connected by a belt 20 for transmission of power. And, there is a door 21 in a front part of the cabinet 1, with a gasket 22 between the door 21 and the tub 2. There is a hanging spring between an inside of an upper portion of the cabinet 1 and an outside of an upper portion of the tub 2, and a friction damper 24 between an inside of a lower portion of the cabinet 1 and a lower side of an outside of the tub 2 for damping vibration of the tub 2 generated during spinning.

However, the related art washing machine has the following disadvantages since driving power of the motor 5 a is transmitted to the drum 3 through the motor pulley 18, and the drum pulley 19, and the belt 20 connecting the motor pulley 18 and the drum pulley 19.

First, there is a loss of energy in a course of driving power transmission because the driving power is transmitted from the motor 5 a to the drum 3, not directly, but through the belt 20 wound around the motor pulley 18 and the drum pulley 19.

And, the driving power transmission from the motor 5 a to the drum 3, not directly, but through many components, such as the belt 20, the motor pulley 18, and the drum pulley 19, causes much noise in the course of power transmission.

The lots of components required for transmission of driving power from the motor 5 a to the drum 3, such as the motor pulley 18, the drum pulley 19 and the belt 20, require many assembly man-hours. And, the more the number of components required for transmission of driving power from the motor 5 a to the drum 3, the more number of spots which require repair, and the more frequent at which repair required.

In summary, the indirect driving power transmission from the motor 5 a to the drum 3 through the motor pulley, the drum pulley, and the belt requires many repair, has much noise, waste of energy, and results in a deterioration of a washing capability.

Moreover, the tub 2 of stainless steel in general in the related art drum washing machine is expensive, has a poor formability, and is heavy.

SUMMARY OF THE INVENTION

Accordingly, the present invention is directed to a structure of a driving unit in a drum type washing machine that substantially obviates one or more of the problems due to limitations and disadvantages of the related art.

An object of the present invention is to provide a structure of driving unit in a drum type washing machine, which can reduce noise, repair and waste of energy, and moreover, improve washing capability.

Another object of the present invention is to provide a structure of driving unit in a drum type washing machine, which has an improved supporting force.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be apparent from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described, the structure of a driving unit in a drum type washing machine having a tub mounted in a cabinet, a drum mounted in the tub, a shaft fixed to the drum for transmission of driving power from the motor to the drum, and bearings mounted on an outer circumference of the shaft at opposite end portions thereof, includes a metallic bearing housing at a central portion of a rear wall of the tub for supporting the bearings mounted on the outer circumferences of opposite end portions of the shaft.

In other aspect of the present invention, there is provided a structure of driving unit in a drum type washing machine including a tub mounted inside of a cabinet, a bearing housing built in a central portion of a rear wall of the tub for supporting a bearing therein, a shaft connected to a drum mounted inside of the tub for transmission of a driving force from a motor to the drum, bearings mounted on an outer circumference of the shaft at opposite end portions thereof respectively, a rotor coupled to a rear end of the shaft, a stator provided inward of the rotor fixed to the tub rear wall, a connector provided between the shaft and the rotor for transmission of a rotating force from the rotor to the shaft for rotating the shaft and the rotor together, and a supporter fitted between the rear wall of the tub and the stator for supporting the stator and maintaining a concentricity when the stator is mounted to the tub rear wall.

In another aspect of the present invention, there is provided a structure of driving unit in a drum type washing machine including a tub of plastic mounted inside of a cabinet, a metallic bearing housing inserted and built in a central portion of a rear wall of the tub having steps of “┐” and “└” forms on an inner circumference for supporting bearings therein, a shaft connected to a drum mounted inside of the tub for transmission of a driving power from a motor to the drum, having a front end portion fixed to a spider in the drum rear wall, a brass bushing press fit on a region of the shaft from a portion exposed in rear of the spider to the front bearing for prevention of rusting of the shaft, and steps on an outer circumference thereof for fixing mounting positions of the front bearing and the rear bearing on the shaft, bearings mounted on the outer circumference of the shaft at opposite end portions thereof respectively, a rotor of steel or steel alloy plate coupled to the rear end portion of the shaft, including a bent portion formed along a circumference thereof having a setting surface for supporting magnets fitted to an inside of a front portion of a sidewall extended forward from a periphery of a rear wall, and a hub at a center of the rear wall having a through hole for a fastening member, such as a bolt, for coupling the rotor to the shaft, a plurality of cooling fins formed around the hub in a radial direction each with a length for blowing air toward the stator when the rotor is rotated for cooling down a heat generated at the stator, an embossing between adjacent cooling fins on the rear wall of the rotor for reinforcing the rotor, and a drain hole in each of the embossings, for drain of water, a stator composing the motor together with the rotor, fixed to the tub rear wall inward of the rotor, a connector of plastic provided between the shaft and the rotor for transmission of a rotating force from the rotor to the shaft for rotating the shaft and the rotor together, and a supporter fitted between the rear wall of the tub and the stator for supporting the stator and maintaining a concentricity when the stator is mounted to the tub rear wall.

In further aspect of the present invention, there is provided a structure of driving unit in a drum type washing machine including a tub mounted inside of a cabinet, a drum mounted inside of the tub, a shaft connected to the drum mounted inside of the tub for transmission of a driving force from a motor to the drum, a front bearing and a rear bearing mounted on an outer circumference of the shaft at opposite end portions thereof respectively, a bearing housing built in a central portion of a rear wall of the tub for supporting the front bearing, a rotor composing the motor together with the rotor, and coupled to the rear end portion of the shaft, a stator fixed to the tub rear wall inward of the rotor to compose the motor together with the rotor, a connector serration coupled to the outer circumference of the shaft in front of the rear bearing and fixed to the rotor, for transmission of a rotating power from the rotor to the shaft, and a bearing bracket fixed to the rear wall of the tub to cover an outside of the rotor and support the rear bearing.

In a still further aspect of the present invention, there is provided a structure of driving unit in a drum type washing machine including a tub of plastic mounted inside of a cabinet, a metallic bearing housing inserted to built in a central portion of a rear wall of the tub having steps on an inner circumference for supporting bearings therein, a shaft connected to a drum mounted inside of the tub for transmission of a driving power from a motor to the drum, having a front end portion fixed to a spider in the drum rear wall, and a brass bushing press fit on a region of the shaft from a portion exposed in rear of the spider to the front bearing for prevention of rusting of the shaft, bearings mounted on the outer circumference of the shaft at opposite end portions thereof respectively, a rotor of steel or steel alloy plate coupled to the rear end portion of the shaft, including a bent portion formed along a circumference thereof having a setting surface for supporting magnets fitted to an inside of a front portion of a sidewall extended forward from a periphery of a rear wall, and a hub at a center of the rear wall having a through hole for a fastening member, such as a bolt, for coupling the rotor to the shaft, a plurality of cooling fins formed around the hub in a radial direction each with a length for blowing air toward the stator when the rotor is rotated for cooling down a heat generated at the stator, an embossing between adjacent cooling fins on the rear wall of the rotor for reinforcing the rotor, and a drain hole in each of the embossings, for drain of water, a stator composing the motor together with the rotor, fixed to the tub rear wall inward of the rotor, a connector of plastic provided between the shaft and the rotor for transmission of a rotating force from the rotor to the shaft for rotating the shaft and the rotor together, a supporter fitted between the rear wall of the tub and the stator for supporting the stator and maintaining a concentricity when the stator is mounted to the tub rear wall, and a bearing bracket fixed to the rear wall of the tub to cover an outside of the rotor and support the rear bearing.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention:

In the drawings:

FIG. 1 illustrates a longitudinal section of a related art drum type washing machine;

FIG. 2A illustrates a longitudinal section of a drum type washing machine in accordance with a first preferred embodiment of the present invention;

FIG. 2B illustrates a detailed enlarged view of “A” part in FIG. 2A;

FIG. 3 illustrates a perspective view with a partial cut away view of the rotor in FIG. 2;

FIG. 4 illustrates an enlarged perspective view of “B” part in FIG. 3;

FIG. 5 illustrates a perspective view of a bottom in FIG. 3 FIG. 6 illustrates a perspective view of the stator in FIG. 2;

FIG. 7 illustrates a perspective view of the connector in FIG.

FIG. 8 illustrates a perspective view of a bottom in FIG. 7; and,

FIG. 9 illustrates a longitudinal section of a driving unit in a drum type washing machine in accordance with a second preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. A first preferred embodiment of the present invention will be explained in detail with reference to FIGS. 2A˜8. FIG. 2A illustrates a longitudinal section of a drum type washing machine in accordance with a first preferred embodiment of the present invention, FIG. 2B illustrates a detailed enlarged view of “A” part in FIG. 2A, FIG. 3 illustrates a perspective view with a partial cut away view of the rotor in FIG. 2, FIG. 4 illustrates an enlarged perspective view of “B” part in FIG. 3, FIG. 5 illustrates a perspective view of a bottom in FIG. 3, FIG. 6 illustrates a perspective view of the stator in FIG. 2, FIG. 7 illustrates a perspective view of the connector in FIG. 2, and FIG. 8 illustrates a perspective view of a bottom in FIG. 7.

The drum type washing machine in accordance with a first preferred embodiment of the present invention includes a tub 2 of plastic mounted inside of the cabinet 1, a drum 3 mounted in the tub 2, a shaft 4 fixed to the drum 3 for transmission of driving power from a motor 5 to the drum 3, bearings 6 a and 6 b fitted on outer circumference of the shaft 4 at both ends thereof, and bearing housings 7 of metal fitted to support the bearings 6 a and 6 b at a central portion of a rear wall 200 of the tub 2. The bearing housing 7 of metal is formed as a unit with the tub rear wall 200 by an inserted injection molding in the injection molding of the tub 2 of plastic. The bearing housing 7 is preferably formed of aluminum. The bearing housing 7 has steps 8 a and 8 b for holding the front bearing 6 a and the rear bearing 6 b fitted in inner circumferences of the bearing housing 7 for preventing the bearings 6 a and 6 b from being fallen off. Of the steps 8 a and 5 b formed on the inner circumferences of the bearing housing 7, the front step 8 a has a form of “┐” for supporting a rear end portion of the front bearing 6 a fitted to a front end of an outer circumference of the shaft 4, and the rear step 8 b has a form of “└” for supporting a front end portion of the rear bearing 6 b fitted to a rear end portion of the shaft 4. And, there are positioning steps 400 a and 400 b on outer circumferences of the shaft 4 disposed inside of the bearing housing 7 which transmits driving power from the motor 5 to the drum 3, for fixing mounting positions of the front bearing 6 a and the rear bearing 6 b on the shaft 4. A front end of the shaft 4 is coupled to a spider 10 in a rear wall of the drum 3, a region of the shaft 4 from a portion exposed in rear of the spider 10 to the front bearing 6 a has a bushing 11 of brass press fit thereon for prevention of rusting, and there is a sealing member 12 on an outer surface of the bushing 11 for preventing ingress of water toward the bearing. There is a rotor 13 of a direct coupling type motor 5 fixed to a center of a rear end of the shaft 4, and a stator 14 of a crown form, consisting the direct coupling type motor 5 together with the rotor 13, fixed to the rear wall 200 inside of the rotor 13.

Referring to FIGS. 3˜5, the rotor 13 of steel or steel alloy plate includes a bent portion formed along a circumference thereof having a setting surface 130 for supporting magnets 13 c fitted to an inside of front of a sidewall 13 b extended forward from a periphery of a rear wall 13 a, and a hub 132 at a center of the rear wall 13 a having a through hole 131 for fastening members 15 a, such as bolts, for coupling the rotor 13 to the shaft 4. An overall form of the rotor 13 is preferably formed by press forming. There are a plurality of cooling fins 133 each formed to have a preset length in a radial direction around the hub 132 of the rotor 13 for blowing air toward the stator 14 during rotation of the rotor 13 for cooling heat generated at the stator 14. The cooling fins 133 are formed by lancing, to bend the cooling fins 133 at a right angle to the rear wall toward the opening to leave through holes 134 for ventilation. There is an embossing 135 between adjacent cooling fins 133 with a drain hole 136 therein for draining water. There are fastening holes 137 for fastening a connector 16 to the rotor 13 and positioning holes 138 for positioning an assembly position of the connector 16 around the through hole 131 in the hub 132 of the rotor 13 at fixed intervals, which connector 16 is serration coupled to an outer circumference of a rear end portion of the shaft 4 exposed to rear of the rear bearing 6 b. The connector 16 is formed of resin having a vibration mode different from the rotor 13 of steel or steel alloy plate, and also serves as a bushing for the rotor 13. As shown in FIGS. 2B, 7 and 8, the connector 16 has fastening holes 162 to correspond to the fastening holes 137 in the hub 132 of the rotor 13 around a circumferential direction of the a peripheral region and a dowel pin 160 between adjacent fastening holes 162 as a unit with the connector 16 for insertion in the positioning hole 138 in the rotor 13 for self alignment of the fastening holes 137 and 162 in the rotor 13 and the connector 16, respectively. The connector 16 has a serration in an inside circumference of the hub 163 matched to the serration in the rear end of the shaft 4, and reinforcing ribs 161 on outer circumference of the hub 163 for reinforcing the hub 163. There is a hub 201 on the rear wall 200 of the tub 2 having the bearing housing 7 inserted therein when the tub is injection molded, and fastening bosses 202 on an outer side of the hub 201 along a circumferential direction at fixed intervals for fastening the stator 14 to the rear wall 200 of the tub 2. There is a supporter 17 between the rear wall 200 of the tub 2 and the stator 14, of a form almost identical to an outline of the tub rear wall 200, fixed to the tub rear wall 200 when the stator 14 is assembled for supporting the stator 14 and maintaining concentricity of the stator 14. The supporter 17 has a fore end brought into a close contact with an inside of ribs 203 at one side of the tub rear wall 200, and a rear end brought into a close contact with an outer circumference of a rear end of the bearing housing 7 which is not enclosed by the hub 132, but exposed. In the meantime, as shown in FIGS. 2B and 6, the stator 14 includes a magnetic core 145 of segregated layers of magnetic material, a frame 140 of resin coated on the magnetic core 145, a coil 142 wound around each of winding parts 141 on an outer circumference of the frame 140, and fastening ribs 143 on an inside of the frame 140 for fastening the stator 14 to the tub rear wall 200.

The operation of the driving unit in a drum type washing machine in accordance with a first preferred embodiment of the present invention will be explained. Upon causing rotation of the rotor 13 by making a current to flow to the coils 142 of the stator 14 in a sequence under the control of a motor driving controller(not shown) fitted on a panel, the shaft 4 serration coupled with the connector 16 fixed to the rotor is rotated, together with the drum 3 as the power is transmitted to the drum 3 through the shaft 4.

In the meantime, the drum type washing machine having the driving unit of the present invention applied thereto serves as follows. The tub 2 of the drum type washing machine of the present invention, formed of a plastic with an excellent heat resistance, is light and has a good formability as the tub 2 is injection molded. Since the bearing housing 7 in the drum type washing machine of the present invention is formed of a metal, such as aluminum and the like, the bearing housing 7 is applicable to a drum type washing machine having a drying cycle as the bearing housing shows no thermal deformation. And, since the metallic bearing housing 7 of the present invention is formed integrated with the tub 2 by inserting the bearing housing 7 in the hub 201 on the tub rear wall 200 before the tub 2 of plastic is injection molded, a separate step for assembling the bearing housing 7 to the tub rear wall 200 can be omitted, which simplifies an assembly process, that reduces assembly man-hours. The form “┐” of the step 8 a in a front portion of an inner circumference of the bearing housing 7 and the “└” form of the step 8 b in a rear portion of an inner circumference of the bearing housing 7 permit to support a rear end of the front bearing 6 a and a fore end of the rear bearing 6 b mounted on outer circumference of the shaft 4 at both end portions thereof. That is, the steps 8 a and 8 b on inner circumferences of the metallic bearing housing 7 on both sides thereof prevent both bearings 6 a and 6 b from being fallen off the bearing housing 7. The positioning steps 400 a and 400 b on outer circumferences of the shaft 4 at front and rear portions thereof permit easy positioning of the front bearing 6 a and the rear bearing 6 b on the shaft 4 in the assembly. The front end portion of the shaft 4 is coupled to the spider 10 in the rear wall, and the brass bushing 11 press fit to the region from the exposed portion outside of the spider 10 of the shaft 4 to the front bearing 6 a prevents rusting of the shaft 4. The sealing member 12 outside of the bushing 11 prevents ingress of water toward the bearing.

In the meantime, the rotor 13 of the direct coupling type motor 5 is mounted on a center of the rear end portion of the shaft 4, with the stator 14 disposed on inner side of the rotor, wherein the bend part having the magnet setting surface 130 is formed along a circumferential direction of the sidewall 13 b extended forward from a periphery of the rear wall 13 a of the rotor 13, for supporting the magnets 13 c when the magnets 13 c are fitted to an inside surface of the rotor 13, to fabricate the rotor with easy. The through hole 131 of the hub 132 at a center of the rear wall 13 a of the rotor 13 permits the fastening member 15 b, such as a bolt or the like, to pass therethrough for fastening the rotor 13 to the shaft 4, and the plurality of cooling fins 133 around the hub 132 of the rotor 13 in a radial direction with a length blow air toward the stator 14 during rotation of the rotor 13 for cooling down a heat generated at the stator 14. The cooling fins 133 are formed by lancing, to direct toward the opening of the rotor 13, and to leave through holes 134 for ventilation. The rotor 13 of steel or steel alloy plate is formed by pressing, which shortens a fabrication time period, that improves a productivity. The embossing 135 between the adjacent cooling fins 133 of the rear wall 13 a of the rotor 13 improves an overall strength of the rotor 13, and the drain hole 136 in the embossing 135 drains water.

In the meantime, the fastening holes 137 for fastening the connector and the positioning holes 138 for fixing an assembly position of the connector 16 around the through hole 131 in the hub 132 of the rotor 13 permits an easy assembly of the connector 16 to the rotor, which connector 16 is serration coupled to the outer circumference of the rear end portion of the shaft 4 exposed to rear of the rear bearing 6 b. That is, once the dowel pins 160 on the connector 16 are inserted in the positioning holes 138 in the rotor 13, the fastening holes 137 and 162 in the rotor 13 and the connector 16 are matched automatically, and by fastening the fastening members 15 c through the fastening holes 137 and 162 in the rotor 13 and the connector 16, the connector 16 and the rotor 13 can be assembled with easy. The connector 16 serves to damp vibration from the rotor 13 to the shaft 4 as the connector 16 injection molded of a resin has a different vibration mode from the rotor 13 of steel or steel alloy plate. The serration 164 in the inner circumference of the hub 163 of the connector 16 is fit to the serration 400 in the rear end portion of the shaft 4, to transmit the rotating force of the rotor 13 to the shaft, directly. The reinforcing ribs 161 on an outer circumference of the hub 163 of the connector 16 reinforce the hub 163.

In the meantime, the fastening bosses 202 along a circumference on an outer side of the hub 201 on the rear wall 200 of the tub 2 at fixed intervals permits to fix the stator 14 to the rear wall 200 of the tub 2 by using the fastening boss 202. The supporter 17 between the rear wall 200 of the tub 2 and the stator 14 having a form almost identical to the outline of the rear wall 200 for being fixed to the rear wall 200 of the tub 2 when the stator 14 is fastened permits the stator 14 being supported and maintained of concentricity. That is, once the supporter 17 is fastened to the fastening bosses 204 on the tub rear wail 200, the fore end of the supporter 17 is brought into close contact with an inside surface of the ribs 203 at one side of the tub rear wall 200 and the rear end of the supporter 17 is brought into close contact with the outer circumference of the rear end portion of the bearing housing 7 at a central portion of the tub rear wall 200, which can not be enclosed, but exposed, by the hub 132, such that the supporter 17 supports the stator 14 as well as maintains a concentricity of the stator 14.

The structure of a driving unit in a drum type washing machine in accordance with a first preferred embodiment of the present invention has the following advantages.

The motor direct coupling structure of the drum type washing machine in accordance with a first preferred embodiment of the present invention permits to reduce repair, and power loss.

The bearing housing of metal in the drum type washing machine in accordance with a first preferred embodiment of the present invention shows no thermal deformation, that allows to apply to a product having a drying function.

The rotor of steel or steel alloy plate formed by pressing in the drum type washing machine in accordance with a first preferred embodiment of the present invention requires a very short fabrication time period, with an improved productivity, because the steel or steel alloy plate pressing has an excellent formability.

And, the magnet setting surface on the rotor of the present invention improves a workability in fitting the magnets, and the drain holes, the cooling fins, and the through holes provided to the rotor can prevent overheating of the motor, improve a reliability of the motor, and prolong a lifetime of the motor.

And, the connector having a vibration mode different from the rotor in the drum type washing machine of the present invention can attenuate the vibration transmitted from the rotor to the shaft, and the supporter can support the stator and maintain a concentricity of the stator.

A driving unit in a drum type washing machine in accordance with a second preferred embodiment of the present invention will be explained with reference to FIGS. 3˜9, in detail. FIG. 9 illustrates a longitudinal section of a driving unit in a drum type washing machine in accordance with a second preferred embodiment of the present invention. The rotor, the stator and the connector in the second preferred embodiment of the present invention are identical to those of the first embodiment, to which the same names and reference symbols are given, and will be explained with reference to FIGS. 3˜8.

The drum type washing machine in accordance with a second preferred embodiment of the present invention includes a tub 2 mounted inside of a cabinet 1, a drum 3 mounted inside of the tub 9, a shaft 4 connected to the drum mounted inside of the tub 3 for transmission of a driving force from the motor 5 to the drum, a front bearing 6 a and a rear bearing 6 b mounted on outer circumferences of the shaft 4 at both end portions thereof respectively, a bearing housing 7 built in a central portion of the rear wall 200 of the tub 3 for supporting the front bearing 6 a, a rotor 13 coupled to the shaft 4, a stator 14 provided inward of the rotor 13 coupled to the tub rear wall 200, a connector 16 serration coupled to an outer circumference of the shaft 4 in front of the rear bearing 6 b and fixed to the rotor 13 for transmission of a rotating force of the rotor 13 to the shaft 4, a supporter 17 fitted between the rear wall 200 of the tub 2 and the stator 14 for supporting the stator and maintaining a concentricity when the stator is mounted to the tub rear wall 200, and a bearing bracket 9 fixed to the tub rear wall 200 for covering outside of the rotor 13 and supporting the front end portion of the rear bearing 6 b. The tub 2 is formed of plastic, and has an opened front and a closed rear wall 200 of which thickness is greater than a thickness of a sidewall, and the bearing housing 7 at the central portion of the rear wall 200 of the tub 2 is formed of a metal, wherein the bearing housing 7 is insert injection molded when the plastic tub 2 is injection molded, such that the bearing housing 7 is integrated with the tub rear wall 200. The bearing housing 7 is preferably formed of an aluminum alloy.

In the meantime, there is a step 7 a on an inner circumference of the metallic bearing housing 7 for supporting the front bearing 6 a to prevent the front bearing 7 from being fallen off the bearing housing 7. The step 7 a on the inner circumference of the bearing housing 7 has a form of “┐” for having a structure which supports a rear end portion of the front bearing 6 a mounted on a front end portion of the shaft 4. The front end portion of the shaft 4 is fixed to a spider 10 in the rear wall 200 of the drum 3, a region of the shaft 4 from a portion exposed in rear of the spider 10 to the front bearing 6 a has a bushing 11 of brass press fit thereon for prevention of rusting, and there is a sealing member 12 on an outer surface of the bushing 11 for preventing ingress of water toward the front bearing 6 a. There connector 16 is serration coupled to the rear end portion of the shaft 4 for connection between the rotor 13 of the direct coupling type motor 5 and the shaft 4, the rotor 13 is fixed to the connector 16 with fastening members 15 c, and the stator 14, forming the direct coupling type motor together with the rotor 13, is fixed to the rear wall 200 of the tub 2 inward of the rotor 13. As shown in FIGS. 3˜5, the rotor 13 of steel or steel alloy plate includes a bend part having a magnet setting surface 130 formed along a circumferential direction of a sidewall 13 b extended forward from a periphery of the rear wall 13 a of the rotor 13, for supporting magnets 13 c fitted to a front portion of an inside surface of the rotor 13, and a hub 132 having a through hole 131 at a center of the rear wall 13 a of the rotor 13 so that a fastening member 15 a, such as a bolt or the like, can pass through for coupling the rotor 13 to the shaft 4. An overall form of the rotor 13 is preferably formed by pressing. There are a plurality of cooling fins 133 each formed to have a preset length in a radial direction around the hub 132 of the rotor 13 for blowing air toward the stator 14 during rotation of the rotor 13 for cooling heat generated at the stator 14. The cooling fins 133 are formed by lancing, to bend the cooling fins 133 at a right angle to the rear wall 13 a toward the opening to leave through holes 134 for ventilation. There is an embossing 135 between adjacent cooling fins 133 with a drain hole 136 therein for draining water. There are fastening holes 137 for fastening a connector 16 to the rotor 13 and positioning holes 138 for positioning an assembly position of the connector 16 around the through hole 131 in the hub 132 of the rotor 13 at fixed intervals, which connector 16 is serration coupled to an outer circumference of a rear end portion of the shaft 4 exposed in rear of the rear bearing 6 b. The connector 16 is formed of resin having a vibration mode different from the rotor 13 of steel or steel alloy plate. As shown in FIGS. 7 ˜9, the connector 16 has fastening holes 162 to correspond to the fastening holes 137 in the hub 132 of the rotor 13 around a circumferential direction of the a peripheral region and a dowel pin 160 between adjacent fastening holes 162 as a unit with the connector 16 for insertion in the positioning hole 138 in the rotor 13 for self alignment of the fastening holes 137 and 162 in the rotor 13 and the connector 16, respectively. The connector 16 has a serration in an inside circumference of the hub 163 matched to the serration in the rear end of the shaft 4, and reinforcing ribs 161 on outer circumference of the hub 163 for reinforcing the hub 163. There is a hub 201 on the rear wall 200 of the tub 2 having the bearing housing 7 inserted therein when the tub is injection molded, and fastening bosses 202 on an outer side of the hub 201 along a circumferential direction at fixed intervals for fastening the stator 14 to the rear wall 200 of the tub 2. There is a supporter 17 between the rear wall 200 of the tub 2, and the stator 14, of a form almost identical to an outline of the rear wall 200, fixed to the tub 2 rear wall 200 when the stator 14 is assembled for supporting the stator 14 and maintaining concentricity of the stator 14. Once the supporter 17 is fastened to the support fastening bosses 204, a fore end of the supporter 17 is brought into close contact with an inside of ribs 203 at one side of the tub rear wall 200, and a rear end thereof is brought into close contact with an outer circumference of a rear end of the bearing housing 7 which is not enclosed by the hub 132, but exposed, thereby the supporter 17 supporting the stator 14 and maintaining a concentricity of the stator. In the meantime, as shown in FIGS. 3 and 6, the stator 14 includes a ring formed frame 140, a coil 142 wound around each of winding parts 141 on an outer circumference of the frame 140, and fastening ribs 143 on an inside of the frame 140 for fastening the stator 14 to the tub rear wall 200.

In the meantime, referring to FIG. 9, there is an “└” formed step 900 b at an inner end portion of the bearing bracket 9 fixed to the tub rear wall 200 to cover an outer side of the rotor 13. And there is a rear bearing fixing member 15 b at an rear end of the shaft 4 for supporting a rear surface of the shaft 4 to prevent the rear bearing from being fallen off the shaft 4.

The operation of the driving unit in a drum type washing machine in accordance with a second preferred embodiment of the present invention will be explained. Upon causing rotation of the rotor 13 by making a current to flow to the coils 142 of the stator 14 in a sequence under the control of a motor driving controller(not shown) fitted on a panel, the shaft 4 serration coupled with the connector 16 fixed to the rotor is rotated, together with the drum 3 as the power is transmitted to the drum 3 through the shaft 4.

In the meantime, the drum type washing machine in accordance with the second preferred embodiment of the present invention driven thus serves as follows. Alike the first embodiment of the present invention, since the tub 1 is formed of a plastic with an excellent heat resistance, the tub 1 is light and has a good formability as the tub 2 is injection molded. Since the bearing housing 7 is formed of a metal, such as an aluminum alloy and the like, the bearing housing 7 is applicable to a drum type washing machine having a drying cycle as the bearing housing shows no thermal deformation. And, since the metallic bearing housing 7 is formed integrated with the tub 2 by inserting the bearing housing 7 in the hub 201 on the tub rear wall 200 before the tub 2 of plastic is injection molded, a separate step for assembling the bearing housing 7 to the tub rear wall 200 can be omitted, which simplifies an assembly process, that reduces assembly man-hours. The step 7 a in an inner circumference of a front portion of the bearing housing 7 in the second embodiment of the present invention supports a rear end of the front bearing 6 a mounted on an outer circumference of the fore end portion of the shaft 4. That is, the “┐” formed step 7 a in a front portion of an inner circumference of the metallic bearing housing 7 of the present invention permits to support the front bearing 6 a without being fallen off the bearing housing 7. And, the “└” formed step 900 b in an end portion of an inner circumference of the metallic bearing bracket 9 covering an outer side of the rotor 13 fixed to the tub rear wall 200 permits to support a front end of the rear bearing 6 b mounted on the rear end portion of the shaft 4, and the rear bearing fixing member 15 b on the rear end surface of the shaft 4 prevents the rear bearing 6 b from being fallen off the shaft 4.

In the meantime, in the second preferred embodiment of the present invention, since the front bearing 6 a is mounted in the bearing housing 7 having insert injection molded in the tub 1, and the rear bearing 6 b is mounted in an inside of a center portion of the bearing bracket 9, a distance between the front and rear bearings 6 a and 6 b on the shaft 4 becomes greater, between which the rotor is mounted. The greater distance between the front and rear bearings 6 a and 6 b permits to withstand a load caused by imbalance of laundry in the drum 1 during spinning better, and a supporting force to the rotor 13 is enhanced as the rotor 13 of the motor is mounted between the front and rear bearings 6 a and 6 b. Alike the first preferred embodiment of the present invention, in the second preferred embodiment of the present invention, the brass bushing 11 press fit to the region from the exposed portion outside of the spider 10 of the shaft 4 to the front bearing 6 a prevents rusting of the shaft 4. And, a likely, the sealing member 12 outside of the bushing 11 prevents ingress of water toward the bearing.

Alike the first preferred embodiment, as shown in FIGS. 3 to 6, the bend part having the magnet setting surface 130 is formed along a circumferential direction of the sidewall 13 b extended forward from a periphery of the rear wall 13 a of the rotor 13, for supporting the magnets 13 c when the magnets 13 c are fitted to an inside surface of the rotor 13, to fabricate the rotor with easy. Alike the first preferred embodiment of the present invention, in the second preferred embodiment of the present invention, the plurality of cooling fins 133 around the hub 132 of the rotor 13 in a radial direction with a length blow air toward the stator 14 during rotation of the rotor 13 for cooling down a heat generated at the stator 14. The cooling fins 133 are formed by lancing to direct toward the opening of the rotor 13, and to leave through holes 134 for ventilation. Since the rotor 13 is formed of steel or steel alloy plate by pressing, which shortens a fabrication time period significantly, a productivity is improved. The embossing 135 between the adjacent cooling fins 133 of the rear wall 13 a of the rotor 13 improves an overall strength of the rotor 13, and the drain hole 136 in the embossing 135 drains water.

In the meantime, the fastening holes 137 for fastening the connector and the positioning holes 138 for fixing an assembly position of the connector 16 around the through hole 131 in the hub 132 of the rotor 13 permits an easy assembly of the connector 16 to the rotor, which connector 16 is serration coupled to the outer circumference of the rear end portion of the shaft 4. That is, once the dowel pins 160 on the connector 16 are inserted in the positioning holes 138 in the rotor 13 the fastening holes 137 and 162 in the rotor 13 and the connector 16 are matched automatically, and by fastening the fastening members 15 c through the fastening holes 137 and 162, the connector 16 and the rotor 13 can be assembled with easy. The connector 16 serves to damp vibration from the rotor 13 to the shaft 4 as the connector 16 injection molded of a resin has a different vibration mode from the rotor 13 of steel or steel alloy plate. The serration 164 in the inner circumference of the hub 163 of the connector 16 is fit to the serration 400 in the rear end portion of the shaft 4, to transmit the rotating force of the rotor 13 to the shaft, directly. The reinforcing ribs 161 on an outer circumference of the hub 163 of the connector 16 reinforce the hub 163.

In the meantime, the fastening bosses 202 along a circumference on an outer side of the hub 201 on the rear wall 200 of the tub 2 at fixed intervals permits to fix the stator 14 to the rear wall 200 of the tub 2 by using the fastening boss 202. The supporter 17 between the rear wall 200 of the tub 2 and the stator 14, having a form almost identical to the outline of the rear wall 200 for being fixed to the rear wall 200 of the tub 2 when the stator 14 is fastened permits the stator 14 being supported and maintained of concentricity. That is, the front end of the supporter 17 is brought into close contact with an inside surface of the ribs 203 at one side of the tub rear wall 200 and the rear end of the supporter 17 is brought into close contact with the outer circumference of the rear end portion of the bearing housing 7 at a central portion of the tub rear wall 200, which can not be enclosed, but exposed, by the hub 132, such that the supporter 17 supports the stator 14 as well as maintains a concentricity of the stator 14.

The structure of a driving unit in a drum type washing machine in accordance with a second preferred embodiment of the present invention has the following advantages.

The motor direct coupling structure of the drum type washing machine of the present invention permits to reduce repair, noise and power loss.

The bearing housing of metal in the drum type washing machine of the present invention shows no thermal deformation, that allows to apply to a product having a drying function.

The rotor of steel or steel alloy plate formed by pressing in the drum type washing machine of the present invention requires a very short fabrication time period, with an improved productivity, because the steel or steel alloy plate pressing has an excellent formability.

And, the magnet setting surface on the rotor of the present invention improves a workability in fitting the magnets, and the drain holes, the cooling fins, and the through holes provided to the rotor can prevent overheating of the motor, improve a reliability of the motor, and prolong a lifetime of the motor.

And, the connector having a vibration mode different from the rotor in the drum type washing machine of the present invention can attenuate the vibration transmitted from the rotor to the shaft, and the supporter can support the stator and maintain a concentricity of the stator.

Particularly, in the second preferred embodiment of the present invention, the greater distance between the front and rear bearings permits to withstand a load caused by imbalance of laundry in the drum 1 during spinning better, and a supporting capability to the rotor is enhanced as the rotor of the motor is mounted between the front and rear bearings.

Thus, by improving a structure of a driving unit of a drum type washing machine, the present invention can reduce noise, repair and power loss, by improving a washing capability, can improve a product reliability, and, by improving workability in fabrication of components of the driving unit, can improve a productivity.

It will be apparent to those skilled in the art that various modifications and variations can be made in the structure of a driving unit in a drum type washing machine of the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. 

1. A motor for an electrical appliance, comprising: a stator; a rotor rotatably mounted around the stator, wherein the rotor has a rear wall and a side wall integrally formed of steel, and wherein magnets are mounted on an inner surface of the sidewall; a connector coupled to the rotor, wherein the connector is formed of an electrically insulating material and wherein the connector includes a plurality of positioning projections which are configured to be inserted into a corresponding plurality of positioning recesses in the rear wall of the rotor; and a rotating shaft that is also coupled to the connector, wherein the connector serves to electrically insulate the shaft from the rotor.
 2. The motor of claim 1, wherein the magnets are evenly spaced around the circumference of the rotor.
 3. The motor of claim 2, wherein locating projections are formed on the inner surface of the sidewall of the rotor to help mount the magnets on the sidewall such that they are evenly spaced around the circumference of the rotor.
 4. The motor of claim 1, wherein an outwardly projecting step is formed in the sidewall of the rotor, and wherein the magnets are mounted on the outwardly projecting step.
 5. The motor of claim 1, wherein an outer rim of the rotor is bent relative to the sidewall to increase the rigidity of the rotor.
 6. The motor of claim 5, wherein the outer rim is bent so that a first portion of the outer rim extends approximately perpendicular to the sidewall of the rotor, and a second portion of the outer rim extends approximately parallel to the sidewall.
 7. The motor of claim 6, wherein the outer rim is bent so the second portion of the outer rim extends approximately parallel to the sidewall and towards the rear wall.
 8. The motor of claim 1, wherein fins are formed in the rear wall of the rotor, the fins comprising portions of the rear wall that have been bent inward towards the stator.
 9. The motor of claim 1, wherein draining holes are formed in the rear wall of the rotor.
 10. The motor of claim 1, wherein the rear wall of the rotor is directly contacted and coupled to the connector.
 11. The motor of claim 1, wherein the connector has a flange so that the connector is detachable and attachable to the rotor at the flange.
 12. A motor for an electrical appliance, comprising: a stator; a rotor rotatably mounted around the stator, wherein the rotor has a rear wall and a side wall integrally formed of steel, and wherein magnets are mounted on an inner surface of the sidewall; a connector coupled to the rotor, wherein the connector is formed of an electrically insulating material and wherein the connector includes a plurality of positioning pins; and a rotating shaft that is also coupled to the connector, wherein the connector serves to electrically insulate the shaft from the rotor.
 13. The motor of claim 12, wherein the connector includes serrations formed in an inner circumference of a hub of the connector which match serrations formed in an outer circumference of the shaft.
 14. The motor of claim 13, wherein the connector includes reinforcing ribs formed on the hub.
 15. The motor of claim 12, wherein the connector is plastic.
 16. The motor of claim 12, wherein the connector includes a plurality of fastening holes and wherein each of the fastening holes are positioned between a pair of the positioning pins.
 17. The motor of claim 12, wherein the rotor includes a plurality of positioning holes, and wherein the positioning pins of the connector are configured to be inserted into the positioning holes in the rotor.
 18. The motor of claim 17, wherein the rotor also includes a plurality of fastening holes configured to receive bolts that couple the connector to the rotor, and wherein the positioning pins of the connector have a larger diameter than the fastening holes of the rotor.
 19. A motor for an electrical appliance, comprising: a stator; a rotor rotatably mounted around the stator, wherein the rotor has a rear wall and a side wall integrally formed of steel, and wherein magnets are mounted on an inner surface of the sidewall; and a connector comprising a flange, wherein the connector is coupled to the rotor at the flange by at least one bolt, and the connector is formed of an electrically insulating material.
 20. The motor of claim 19, wherein the connector is readily detachable from the rotor.
 21. The motor of claim 19, wherein the rotor comprises a fin that extends towards the stator, and wherein the fin is formed from the rear wall of the rotor.
 22. The motor of claim 21, wherein the fin is formed by stamping out a portion of the rear wall. 